Short Circuit Self-Protected DC-to-DC Buck Converters

ABSTRACT

Buck converters with self-protection against short circuit at the buck converter outputs and intrinsic soft start-up circuitry are disclosed. The methods and circuits disclosed are applicable for PFM and PWM modulated converters. The methods disclosed are also applicable for boost converters against shorts between boosted voltage and supply voltage.

TECHNICAL FIELD

This disclosure relates generally to electronic circuits and relatesspecifically to novel short circuit self-protection methods and circuitsfor Buck Converters and also boost converters which are self-protectedagainst short circuits.

BACKGROUND

There is a growing demand for switching Buck Converters. A veryimportant feature of buck converters is the capability to withstand anOutput Short Circuit.

Currently most of the commercial or known solutions to protect a Buckfrom a damage of a short circuit rely on as follows:

-   -   External components;    -   Cycle to cycle current limit;    -   Frequency Foldback Technique;    -   Hiccup Mode;

It is obvious that the use of external components is expensive and itdoesn't contribute to robustness of the converter itself.

The Cycle to Cycle current limit and the Frequency Foldback Technique,as outlined later, need a complex design effort and, if not carefullydesigned, does not always guarantee a reliable short circuit protection.

Moreover in the above protections the control loop must be carefullychecked to avoid instability issues.

The Hiccup Mode instead creates a huge in-rush of current every cycleand for this reason it can create problems at the system level.

All those methods rely on the designer's ability to identify the worstcase condition and define the trade-off between frequency, stability,duty-cycle, minimum turn-off time, minimum turn-on time, inductor andcapacitance parameters.

It is a challenge to designers of buck converters or boost converters toovercome the disadvantages mentioned above.

SUMMARY

A principal object of the present disclosure is to achieve aself-protection against a short circuit applied to a buck converteroutput or a boost converter output as well as it is an intrinsic softstart-up circuitry

A further object of the present disclosure is to achieve a simplerealization of self- protection against a short circuit applied to abuck converter output or a boost converter output.

A further object of the present disclosure is to achieve a simplerealization of self-protection against a short circuit applied to a buckconverter output or a boost converter output.

A further object of the present disclosure is to achieve self-protectionagainst a short circuit applied to a buck converter output or a boostconverter output independent from frequency, minimum Turn On time,minimum Turn Off time, Duty Cycle, Inductor and Capacitance parameters.

A further object of the present disclosure is to achieve robust andstable self-protection against a short circuit applied to a buckconverter output or a boost converter output.

Furthermore an object of the present disclosure is to achieve aself-protection against a short circuit applied to a buck converteroutput or a boost converter output which can be applied to basically allmodulations loop including CCM PFM.

Moreover an object of the present disclosure is to achieve a robust andstable self-protection against a short circuit applied to a buckconverter output or a boost converter output which doesn't createin-rush current issues.

In accordance with the objects of this disclosure a buck converterenabled for self-protection of a buck converter against short circuit atthe output of the buck converter and for an intrinsic soft start-uppreventing excessive in-rush currents has been achieved. The buckconverter disclosed firstly comprises: an output stage comprising a highside switch and a low side switch both connected in series, wherein theoutput stage is capable of being connected to a coil having a firstterminal at a node between the high side switch and the low side switch,a minTon unit defining a minimum on-time of the high switch, and aminToff time unit configured to limiting a maximum switching frequencyof the buck converter. Furthermore the buck converter comprises acircuitry configured to detecting a short circuit or an overloadcondition of the buck converter wherein the overload condition includesreaching a current limit of a current through the coil, a current coillow crossing detector capable of detecting when the current through thecoil reaches a defined low crossing value which may be zero and issuinga corresponding signal, and a control logic configured to performing aself-protection loop by enabling and managing a recovery from a short oroverload condition of the buck converter.

In accordance with the objects of this disclosure a method forself-protection of a buck converter against short circuit at the outputof the buck converter and for an intrinsic soft start-up preventingexcessive in-rush currents has been achieved. The method disclosedcomprises the steps of: (1) providing a buck converter comprising a coiland an output stage comprising a high side switch and a low side switch,(2) checking if there is a short or an overload condition at the outputof the buck converter by a correspondent circuitry and, if it so, go tostep (3), else repeat step (2), and (3) ensuring the output stage staysin Tri-state once the coil current reaches zero until an internalcontrol directs the current to flow in a same direction of the currentlimit that has been previously triggered and recovering normal operationof the buck converter and go back to step (2).

BRIEF DESCRIPTION OF THE DRAWINGS

In the accompanying drawings forming a material part of thisdescription, there is shown:

FIG. 1 shows a block diagram of a buck converter using DCM and PFMoperational mode, which is protected against short circuit.

FIG. 2 shows a time diagram of the output voltage V_(OUT), the referencevoltage V_(REF), the coil current I_(L), and the load current I_(LOAD)of the buck converter of FIG. 1.

FIG. 3 shows a block diagram of a buck converter without protectionagainst short circuit known to the inventor, using CCM and PFMoperational mode.

FIG. 4 shows a time diagram of the output voltage V_(OUT), the referencevoltage V_(REF), the coil current I_(L), and the load current I_(LOAD)of the buck converter of FIG. 3.

FIG. 5 shows a general Buck converter controlled with a PWM thatfeatures a Minimum Turn on Time

FIG. 6 shows a short circuit condition for an unprotected buck converterin DCM PFM.

FIG. 7 shows the case of a short to ground applied at VOUT (Forced azero voltage between VOUT and ground VOUT=OV) of a buck converter in CCMPFM.

FIG. 8 shows the case of a short applied when the short is applied whileVOUT is below VREF of a buck converter in CCM PFM.

FIG. 9 shows the waveforms of the coil current and the output voltagefor a buck converter shorted to ground in PWM.

FIG. 10a shows waveforms of the coil current I_(L) for a Buck converterin CCM with Short Circuit Protection and VOUT shorted to ground.

FIG. 10b illustrates the waveforms of FIG. 10a zoomed in.

FIG. 11 illustrates a 1^(st) implementation of the Short CircuitSelf-Protection in a CCM PFM.

FIG. 12 illustrates a 2nd implementation of the Short CircuitSelf-Protection in a CCM PFM.

FIG. 13 shows waveforms of the coil current, Vout, CLK pulses, HIGH_Zsignal, and CLK_LIMIT signal in case of a output shorted to groundVOUT=0 in a CCM PWM operation.

FIG. 14 shows a short protection circuit implementation in PWM forVSHORT<=VREF.

FIG. 15 shows a short protection circuit implementation in PWM for anyVSHORT.

FIG. 16 shows a PWM start-up of a buck converter with high cap at theoutput.

FIG. 17 depicts a flowchart of a method for self-protection of a buckconverter against short circuit at the output of the buck converter andfor an intrinsic soft start-up preventing excessive in-rush currents.

DETAILED DESCRIPTION

This disclosure is about a novel self-protection method and circuitagainst short circuit for Buck and Boost Converters and itsImplementation in particular in two of the most common modulations:Pulse Frequency Modulation (PFM) and Pulse Width Modulation (PWM).

Disclosed are embodiments of methods and circuits to achieve aself-protection against short circuit applied to a buck converter outputor a boost converter output as well including an intrinsic soft start-upcircuitry wherein the converter operate using different modulation loopssuch as CCM PFM or PWM.

Discontinuos Conduction Mode (DCM) and PFM Functional Description

FIG. 1 shows a block diagram of a buck converter with protection againstshort circuit known to the inventor, using DCM and PFM operational mode.FIG. 2 shows a time diagram of the output voltage V_(OUT), the referencevoltage V_(REF) 23, the coil current I_(L), and the load currentI_(LOAD). The currents and voltages shown in FIG. 2 correspond to thebuck converter shown in FIG. 1. FIG. 2 shows the coil current I_(L) 20,load current I_(LOAD) 21, a programmed current peak PCP 24 of the coilcurrent I_(L), the output voltage V_(OUT) 22 and the reference voltageV_(REF) 23.

As shown in FIG. 1 and in FIG. 2, starting from a high impedance (Hi-Z)condition of the output stage at point of time t₁, when the outputvoltage V_(OUT) goes below the reference voltage V_(REF) the UnderVoltage Comparator UVC 7 trips and the flip-flop 9 is Set. As aconsequence the high-side in the Output Stage 1 is enabled, so the HighSide Current Sense HCS 2 and the Over Current Comparator OCC 12 that isblanked for a minimum Turn On Time (minTon) 11. During this phase thehigh side current (that is also the current I_(L) in the coil 4) issensed by HCS 2 and converted in an internal amplified replica that iscompared to an internal reference (IREF) function of the programmedcurrent peak PCP 24, as shown in FIG. 2. The High Side Current Sense HCS2 comprises the internal amplified replica. Once the current in the coilreaches the programmed current peak PCP 24 the OCC 12 trips and resetsthe flip-flop 9. From this point the output low side is enabled as wellas the Low Side Current Sense (LSCS) 3 and the Zero Crossing CurrentComparator (ZCCC) 10. The current in the coil will decrease and once itreaches zero the ZCCC 10 will trip bringing the output stage in HighImpedance (High-Z) mode. Because of the logic block AND 8 only at thispoint, if VOUT is still below, the reference voltage VREF the loop canrestart.

The blocks 13 and 5 are respectively a general logic inverter gate and aBuck Output Capacitance.

Continuous Conduction Mode (CCM) PFM Functional Description

FIG. 3 shows a block diagram of a buck converter without protectionagainst short circuit known to the inventor, using CCM and PFMoperational mode. FIG. 4 shows a time diagram of the output voltageV_(OUT), the reference voltage V_(REF), the coil current I_(L), and theload current I_(LOAD) of the buck converter of FIG. 3. As shown in FIG.4, starting from a condition of output stage in Hi-Z when the VOUT 41goes below the reference voltage VREF 40 the Under Voltage Comparator(UVC) 7 trips and the flip-flop 9 is Set. As a consequence the high-sidein the Output Stage 1 is enabled, so the high side current sense (HSCS)2 and the OCC 12 that is blanked for a minimum Turn On Time (minTon) 11.During this phase the current in the high side (that is also the currentin the coil 4) is sensed and converted in an internal amplified replicathat is compared to an internal reference IREF_MAX function of theprogrammed current peak. Once the current in the coil reaches theprogrammed current peak the OCC 12 trips and resets the flip-flop 9.From this point the output low side 1 is enabled as well as the Low SideCurrent Sense (LSCS) 3 and the ZCCC 10. The current in the coil willdecrease and this time (on the contrary of the DCM PFM) after a minimumToff time, indicated by block 14, if VOUT voltage is still below therefence voltage VREF (since the AND gate 9 is no longer gated from theminToff time) the loop can restart. In any case if the current in thecoil will reach zero the ZCCC 10 will trip bringing the output stage 1to High-Z (High Impedance).

Furthermore the circuit of FIG. 3 comprises an Inverter gate 13 and theBuck Output Capacitance 5.

Pulse Width Modulation (PWM) Functional Description

The PWM (Pulse Width Modulation) is the most common modulation used byDC-DC converters.

There are too many possible implementations of a PWM control loop andfor that reason they will not be described in detail. Anyway asreference in FIG. 5 there is a general Buck converter controlled with aPWM that features a Minimum Turn on Time (minTon). The Clock 8 sets theflip flop 10 periodically while the PWM loop controls the Turn On/Offtime based on the feedback coming from the actual output voltage VOUT,reference voltage VREF(ideal output voltage), HSCS 2 and LSCS 3 andminTon unit 9.The minimum Ton period is a value which may be defined inthe minTon unit 9.

The blocks 4 and 5 are respectively the Buck Coil and the Buck OutputCapacitance. Block 11 is a general logic inverter.

Short Circuit Behavior for an Unprotected Buck Converter in DCM/PFM

In case of a short circuit at the Buck converter output voltage, if thevoltage is applied at VOUT is above the target voltage (VOUT>=VREF), theBuck converter will stay in tristate condition.

FIG. 6 shows a short circuit condition for an unprotected buck converterin DCM PFM, i.e. a short to ground applied at VOUT (Forced a zerovoltage between VOUT and ground VOUT=OV). If instead the short appliedat VOUT is below the reference voltage VREF (VOUT<VREF) the Buckconverter will try to deliver as much as current it can. Luckily in DCMPFM the maximum deliverable current even in case of a short is limitedby the intrinsic control loop to at maximum half the programmed peakcurrent.

Short Circuit Behavior for an Unprotected Buck Converter in CCM/PFM

In case of a short circuit at the Buck output voltage, if the voltageshort applied at VOUT is above the target voltage (VOUT>=VREF) the Buckwill stay in tristate. If instead the short applied at VOUT is below thereference voltage VREF (VOUT<VREF) the Buck will try to deliver as muchas current it can. This time in CCM PFM the maximum deliverable currentdue to the constraints of the minToff and minTon is well above theprogrammed peak current.

In fact the maximum switching frequency is not only limited by theminToff time but also by minTon time that is intrinsically based on thedesign. In fact when the output stage high side is turned on the currentcomparator should start to work. In order to avoid that it trips for theinitial in-rush current a blanking time must be implemented. That is theminTon time. It can happen that due to the design constraints the minTonand minToff cannot be correlated and so are selected independently. Inthis case there is no guarantee that the Buck will work correctly duringa short. Due to those limitations the current in the coil will continueto increase until a new steady state is reached. Unfortunately this newsteady state can require the coil current to exceed the maximum allowedcurrent and eventually destroy the coil.

FIG. 7 shows the case of a short to ground applied at VOUT (Forced azero voltage between VOUT and ground; VOUT=OV).

FIG. 8 shows the case of a short applied when the short is applied whileVOUT is below VREF. In this case the Buck converter turns on the highside. Once the programmed current limit is reached the low side isturned on, but after the period of time minToff, VOUT is still belowVREF so the Buck converter has no choice to turn on again the high sideat least for a minTon period even if the current in the coil is abovethe current limit. With a short applied the Buck converter in CCM PFMcan only work with minTon and minToff and for the reason explained abovethe current in the coil cannot be correctly limited and eventually thecoil can be destroyed.

Short Circuit Behavior for a Cycle to Cycle Current Limit Protected BuckConverter in PWM.

FIG. 9 shows the waveforms of the coil current and the output voltagefor a buck converter shorted to ground in PWM.

For simplicity reason, the case of a short circuit at the buck converteroutput voltage is considered when the voltage short applied at VOUT isbelow the target voltage (VOUT<VREF). The case of a Buck that features apositive cycle to cycle current limit and Minimum Turn On Time minTonperiod is also considered.

In this case, like in the case of CCM PFM although the current limit istriggered, the buck converter must stay on for at least a minTon period.Hence the coil current increases until a new steady state is reachedagain. Although the current limit is set around 600 mA, because of thesetting of minTon the steady state can only be reached at 2 A of coilcurrent.

Implementations of the short circuit self-protection in CCM PFMmodulation mode:

New Short Circuit Self-Protection Method:

In order to limit the current in the coil in case of a Short Circuit(and also at the start up, as shown in FIG. 16) a novel method isdisclosed:

The basic idea for this short circuit self- protection can be brokendown in 3 steps:

-   -   1. First a circuit must detect the short/overload condition.    -   2. If there is a short detected the current in the coil must be        limited in his peak value and once this limit is triggered, the        current must be as soon as possible inverted until it is low        enough (respectively high enough for negative currents) not to        exceed the limit during the next forced on- time period. This        can apply either to the on-time period of the high side switch        or the on-time period of the low side switch (normally called        t_(off)).    -   3. Once the current reaches zero or a value close to zero, the        output stage must stay in Tri-state until the internal control        directs the current to flow in the same direction of the current        limit that has been previously triggered. At this point the        normal operation can be recovered. (Anyway if the short is still        detected the point 2 and 3 will be repeated).

Implementations of the Short Circuit Self-Protection in a CCM PFM:

In order to detect the condition of short/overload 2 possible solutionswill be disclosed:

-   -   1) Use of an additional Over Current Comparator (OCC) output        with the option to be in combination with the minTon period unit        (Ton); (1^(st) Implementation), as shown in FIG. 11.    -   2) Use of the minTon time unit in combination with the OCC        output; (2^(nd) implementation), as shown in FIG. 12.

Referring to FIG. 11, in the 1^(st) implementation, if there is a shortthat forces VOUT<VREF, detected by the Under Voltage Comparator (UVC) 7,first the high side current sense unit 2 will trigger the primarycurrent limit comparator OCC 12 then after the first minimum turn ontime of the high switch, as defined in the minTon unit 11, the secondOCC 15 may be optionally triggered by the minTon unit 11 and since thebuck converter is not in high-Z (tristate, HIGH_Z low) the signalCLK_LIMT is set to 0 by the flip-flop 16. At this point because of theAND gate 8 the current in the coil is forced to decrease until itreaches the low crossing value Izero_ref as input to ZCCC unit 10. Thelow crossing value IZERO_ref may be zero or close to zero. The momentthe current in the coil reaches Izero_ref, the signal HIGH_Z is toggledhigh, the buck is put in High-Z and since the flip-flop 16 is reset andthe signal CLK_LIMIT is 1 again, the AND 8 is no longer gated and theBuck converter can recover the normal operation. In case, the short isnot removed, the short self-protection loop will be repeated.

It should be noted that minimum Toff time and minimum Ton time may bedifferent.

In the 2^(nd) Implementation shown in FIG. 12, if there is a short thatforce VOUT<VREF, first the current will trigger the current limitcomparator OCC 12 then just after the following minimum turn on time(minTon) of the high switch, since the OCC 12 will be still high and thebuck is not in high-Z (tristate, HIGH_Z low) the signal CLK_LIMT is setto 0 by the flip-flops 15 and 16. At this point, because of the AND gate8, the current in the coil is forced to decrease until it reaches thelow crossing value Izero_ref. The moment it reaches Izero_ref the signalHIGH_Z is toggled high, the buck is put in High-Z and since theflip-flop 16 is reset and the signal CLK_LIMIT is 1 again, the AND gate8 is no longer gated and the Buck can recover the normal operation. Incase the short is not removed the short self-protection loop will berepeated.

The minToff time of block 14 defines the maximum switching frequency andhence avoids the buck converter to go to 100% duty cycle

FIG. 10a shows waveforms of the coil current I_(L) for a Buck converterin CCM with Short Circuit Protection and VOUT shorted to ground and FIG.10b illustrates the waveforms of FIG. 10a zoomed in. FIG. 10b shows theprogrammed current limit 100 and minimum ton period 101.

Implementations of the Short Circuit Self-Protection in PWM:

In FIGS. 14 and 15 there are 2 implementations for the Short CircuitSelf-Protection in PWM.

In particular, in FIG. 14 there is the implementation for a ShortCircuit protection only for VOUT>VREF. In FIG. 15 the implementation iscomplete to allow a Short Circuit protection for any value of a short atVOUT.

Implementations of the Short Circuit Self-Protection in PWM forVSHORT<=VREF

FIG. 14 shows a short protection circuit implementation in PWM forVSHORT<=VREF. Compared to the PWM without protection in FIG. 5 thefollowing elements have been added in FIG. 14:

-   -   ZCCC (Current Coil Low Crossing Detector) 12 (Toggle high when        the current in the coil reaches a defined value Izero_ref, it is        latched once triggered and is reset low by the inverter 13        output HIGH_Z=0 if reset=0);    -   Inverter gate 13;    -   AND gate 14;    -   OCC (Over Current Comparator) 15;    -   flip-flop edge triggered D-type with positive logic reset 16;    -   flip-flop edge triggered D-type with negative logic reset 17;    -   AND gate 18; and    -   OR gate with one input active low 19;

In case of a short applied at VOUT that forces VOUT<VREF when thecurrent exceeds the programmed current limit (function of IREF) theoutput of the OCC 15 forces the net CLK_LIMIT low.

As consequence the CLK signal is gated 18 and the Output Stage low sideis enabled (reset is forced on the flip-flop 10 by the OR gate 19) . Atthe same time the ZCCC 12 is enabled. Once the current in the coilreaches zero (or Izero_ref) the ZCCC12 trips, the signal HIGH_Z is highand the Output Stage is forced in Tristate. Because of HIGH_Z is high,the output of the flip-flop 16 is high and on the rising edge of thenext CLK the signal CLK_LIMIT is forced high, the flip-flop (10) is setand the output is no longer in Tristate because the output of AND gate14 is forced low.

The normal PWM loop can now take over or, if the short is still applied,it will be detected again and the loop described above will be repeated.

FIG. 13 shows waveforms of the coil current, Vout, CLK pulses, HIGH_Zsignal, and CLK_LIMIT signal in case of a output shorted to groundVOUT=0 in a CCM PWM operation.

Implementation of a Full Short Circuit Self-Protection in PWM (anyVSHORT).

FIG. 15 shows a short protection circuit implementation in PWM for anyVSHORT. Compared to the PWM without protection in FIG. 14 the followingelements have been added in FIG. 15:

-   -   (20) AND gate 20;    -   (21) OR gate with one input active low 21;    -   (22) OCC (Over Current Comparator) 22;    -   (23) flip-flop edge triggered D-type with positive logic reset        23; and    -   (24) flip-flop edge triggered D-type with negative logic reset        24.        The inverter gate 13 shown in FIG. 14 has been now changed in a        NAND gate 130 in FIG. 15.

The case of a short applied at VOUT that forces VOUT<VREF has beenalready outlined above.

In the case of a short VOUT>VREF when the current exceeds the programmednegative current limit (function of IREF_N) the output of the OCC 22forces the net RST_LIMIT low.

As consequence the RST signal is gated 20 and the Output Stage low sideis enabled (reset is forced on the flip-flop 10 by the OR gate 21).During the output low side is enabled the high side is disabled.

At the same time the ZCCC 12 is enabled. Once the current in the coilreaches Izero_ref the ZCCC 12 trips, the signal HIGH_Z is high and theOutput Stage is forced in Tristate. Because of the HIGH_Z is high, theoutput of the flip-flop 22 is high and on the rising edge of the nextRST the signal RST_LIMIT is forced high, the flip-flop 10 is reset andthe output is no longer in Tristate because the output of AND gate14 isforced low.

The normal PWM loop can now take over or, if the short is still applied,it will be detected again and the loop described above will be repeated.In this case the ZCCC 12 has to be capable to detect the coil currentcrossing in the high-side switch as well as in the low side switch.

It has to be noted that the short circuit self-protection implementationdisclosed in the document is also an intrinsic soft start-upimplementation. All implementations disclosed above work also anintrinsic start-up circuitry. FIG. 16 shows a PWM start-up of a buckconverter with high cap at the output.

Furthermore it has to be noted that a short to GROUND in a buckconverter is similar to a short at the output of a boost converter to asupply voltage of a boost converter. Therefore the methods disclosedabove for buck converters can also be applied to boost converters.

FIG. 17 shows a flowchart of a method for self-protection of a buckconverter against short circuit at the output of the buck converter andfor an intrinsic soft start-up preventing excessive in-rush currents. Afirst step 170 depicts provision of a buck converter comprising a coiland an output stage comprising a high side switch and a low side switch.The next step 171 shows checking if there is a short or an overloadcondition at the output of the buck converter by a correspondentcircuitry and, if it so, go to step 172, else repeat step 171. Step 172describes limiting a current through the coil in its peak value and oncethis limit is triggered, inverting the current as soon as possible untilit is low enough in its absolute value not to exceed this limit valueduring a next forced on-time period, wherein the on-time period applieseither for the high-side switch or for the low-side and the last step173 illustrates ensuring the output stage stays in Tri-state once thecoil current reaches zero until an internal control directs the currentto flow in a same direction of the current limit that has beenpreviously triggered and recovering normal operation of the buckconverter and go back to step 171.

While the disclosure has been particularly shown and described withreference to the preferred embodiments thereof, it will be understood bythose skilled in the art that various changes in form and details may bemade without departing from the spirit and scope of the disclosure.

What is claimed is:
 1. A buck converter enabled for self-protection of abuck converter against short circuit at the output of the buck converterand for an intrinsic soft start-up preventing excessive in-rushcurrents, comprising: an output stage comprising a high side switch anda low side switch both connected in series, wherein the output stage iscapable of being connected to a coil having a first terminal at a nodebetween the high side switch and the low side switch; a minTon unitdefining a minimum on-time of the high switch; a minToff time unitconfigured to limiting a maximum switching frequency of the buckconverter; a circuitry configured to detecting a short circuit or anoverload condition of the buck converter wherein the overload conditionincludes reaching a current limit of a current through the coil; acurrent coil low crossing detector capable of detecting when the currentthrough the coil reaches a defined low crossing value which may be zeroand issuing a corresponding signal; and a control logic configured toperforming a short self-protection loop by enabling and managing arecovery from a short or overload condition of the buck converter. 2.The buck converter of claim 1, wherein the circuitry configured todetecting a short circuit or an overload condition of the buck convertercomprises a high side switch current sense unit and a first comparatorconfigured to comparing the result of the high side current sensing witha reference current.
 3. The buck converter of claim 1, wherein the buckconverter is operated in Continuous Conduction Modulation (CCM) PulseFrequency Modulation (PFM), wherein the control logic is configured toperforming a short self-protection loop and wherein, if the circuitryconfigured to detecting a short circuit or an overload condition of thebuck converter signals a short, a second comparator configured tocomparing the result of the high side current sensing with a referencecurrent is triggered and then initiates a signal CLK_LIMIT to be set tolow, while the buck converter is set in a low impedance mode and at thesame time the current through the coil is forced to decrease until itreaches the low crossing value and at the moment the coil currentreaches the low crossing value the buck converter is set to highimpedance mode again, the signal CLK_limit is set high and the buckconverter can recover normal operation and, if the short is not removed,the short self-protection loop is repeated.
 4. The buck converter ofclaim 3, wherein the second comparator configured to comparing theresult of the high side current sensing with a reference current istriggered by the minTon unit.
 5. The buck converter of claim 4, whereina flip-flop, initiated by the second comparator, sets the signalCLK_LIMIT to low if a short has been detected and the buck converter isin low impedance mode and the flip-flop sets the signal CLK_LIMIT tohigh at the moment the coil current reaches the low crossing value andthe buck converter is in high impedance mode.
 6. The buck converter ofclaim 3, wherein the buck converter is set, in case of a short, in a lowimpedance mode by a means to sense the current flowing through the lowside switch and a comparator configured to comparing the result of thelow side current sensing with a reference current representing the lowcrossing currentvalue, wherein the output of the comparator is connectedto the output stage and sets the impedance mode of the buck converter,wherein the comparator sets the impedance mode to high when the low sidecurrent sensed is equal to the low crossing value.
 7. The buck converterof claim 6 wherein the reference current representing the low crossingcurrent value has a value of zero or close to zero.
 8. The buckconverter of claim 1, wherein the buck converter is operated inContinuous Conduction Modulation (CCM) Pulse Frequency Modulation (PFM),wherein the control logic is configured to performing a shortself-protection loop and wherein, if the circuitry configured todetecting a short circuit or an overload condition of the buck convertersignals a short, two flip-flops are triggered after a defined minimumturn-off time of the high switch and then a signal CLK_LIMIT is set tolow, while the buck converter is set in a low impedance mode and at thesame time the current through the coil is forced to decrease until itreaches the low crossing value and at the moment the current reaches thelow crossing value the buck converter is set to high impedance modeagain, the signal CLK_limit is set high and the buck converter canrecover normal operation and, if the short is not removed, the shortself-protection loop is repeated.
 9. The buck converter of claim 8,wherein a first flip-flop of said two flip-flops receives a signalindicating a short condition from said circuitry configured to detectinga short circuit or an overload condition of the buck converter andtriggers a second of said two flip-flops to setting the signal CLK_LIMITto low if a short has been detected and the buck converter is in lowimpedance mode and second flip-flop sets the signal CLK_LIMIT to high atthe moment the coil current reaches the low crossing value and the buckconverter is in high impedance mode.
 10. The buck converter of claim 8,wherein the buck converter is set, in case of a short, in a lowimpedance mode by a means to sense the current flowing through the lowside switch and a comparator configured to comparing the result of thelow side current sensing with a reference current representing the lowcrossing value, wherein the output of the comparator is connected to theoutput stage and sets the impedance mode of the buck converter, whereinthe comparator sets the impedance mode to high when the low side currentsensed is equal to the low crossing value.
 11. The buck converter ofclaim 1, wherein the buck converter is operated in Pulse WidthModulation (PWM), wherein the control logic is configured to performinga short self-protection loop and wherein, if the circuitry configured todetecting a short circuit or an overload condition of the buck convertersignals a short, a signal CLK_LIMIT is set low, a clock signal CLK isgated, the low side of the output stage is enabled and at the same timethe current through the coil is forced to decrease until it reaches thelow crossing value and at the moment the current reaches the lowcrossing value the buck converter is set to high impedance mode again,the output stage is forced to Tristate mode and on a rising edge of anext clock pulse CLK the signal CLK_LIMIT is set high, the output stageis no longer in Tristate mode and the buck converter can recover normaloperation and, if the short is not removed, the short self-protectionloop is repeated.
 12. A method for self-protection of a buck converteragainst short circuit at the output of the buck converter and for anintrinsic soft start-up preventing excessive in-rush currents,comprising the steps of: (1) providing a buck converter comprising acoil and an output stage comprising a high side switch and a low sideswitch; (2) checking if there is a short or an overload condition at theoutput of the buck converter by a correspondent circuitry and, if it so,go to step (3), else repeat step (2); and (3) ensuring the output stagestays in Tri-state once the coil current reaches zero until an internalcontrol directs the current to flow in a same direction of the currentlimit that has been previously triggered and recovering normal operationof the buck converter and go back to step (2).
 13. The method of claim12 wherein the method is applicable for PFM and PWM modulation.
 14. Themethod of claim 12 wherein the method is also applicable to boostconverters against shorts between a boosted voltage and supply voltage.